Illuminating emblem device and methods of manufacture and use

ABSTRACT

Described herein includes embodiments of an illuminating emblem device that is configured to be coupled to a vehicle and/or device. Some implementations of the illuminating emblem device include a light assembly that is configured to provide a uniform (or substantially uniform) distribution of light along a front housing part or front panel of the illuminating emblem. For example, in some implementations, the illuminating emblem device can include a light diffusing filler that diffuses light emitted from the light assembly to assist with uniformly distributing light emitted through the front housing part. Various other embodiments of the illuminating emblem device and associated methods of manufacturing are described.

CROSS-REFERENCE TO RELATED APPLICATION

The current application claims priority under 35 U.S.C. §119(e) to U.S.Provisional patent application Ser. No. 62/365,050 filed on Jul. 21,2016 and entitled “Illuminating Emblem Device And Methods Of ManufactureAnd Use,” which is incorporated by reference herein in its entirety.

TECHNICAL FIELD

The subject matter described herein relates to various embodiments of anilluminating emblem device, as well as methods of use and manufacturingof same.

BACKGROUND

Nameplates or emblems have been made to identify various devices, suchas vehicles, for decades. Through the years, various methods have beenimplemented to make such emblems. For example, one method includesdie-casting metal that is polished and/or plated to produce ahigh-polished chrome emblem. Another method includes molding plastic andmetal plating the outer surface of the molded plastic. Several emblemsare made to appear 3-dimentional (3D) with a metal coating.

Vehicle manufacturers typically attach at least one emblem to eachvehicle (e.g., car, motorcycle, truck, etc.) to identify a variety ofaspects related to each vehicle, such as the make and model of thevehicle. Some emblems can add to the aesthetics of a vehicle and can beconfigured in any number of shapes, sizes, and colors. Emblems have alsobeen used to identify various other manufactured products, such ashousehold durable goods (refrigerators, stoves, washing machines, etc.)and recreational products (RV's, boats, motorcycles, skis, scooters,etc.).

A shortcoming of emblems can include their lack of visibility at nightand during low light conditions. Attempts to improve emblem visibilityin dark or low-light conditions have resulted in less than desirableresults. Such attempts include, for example, the use of an outside lightsource directed onto the emblem. However, such approaches haveshortcomings. These shortcomings can include an aesthetically unpleasantappearance, insufficient and/or non-uniform lighting, easily damaged,and expensive to install and manufacture. Other shortcoming can includeexcessive heat from an illumination source that can damage the emblemand/or surrounding structure, not achieving weather tight protection forelectrics, and/or high costs. Accordingly, a need exists for improvedilluminating emblems.

SUMMARY

Aspects of the current subject matter include various embodiments of anilluminating emblem assembly. In one aspect, an emblem assembly includesa housing having a front housing part coupled to a back housing part andan inner cavity contained between the front housing part and backhousing part. The emblem assembly can include a light assemblyconfigured to emit light and positioned within the inner cavity. Theemblem assembly can further include a light diffusing filler within theinner cavity and positioned adjacent the light assembly to diffuse atleast some of the light emitted from the light assembly, wherein atleast a part of the front housing part allows the diffused light emittedfrom the light assembly to pass therethrough.

In some variations, one or more of the following features can optionallybe included in any feasible combination. The light assembly can includeat least one light emitting component coupled to a light panel, and thelight panel can be configured to deflect light emitted from the at leastone light emitting component towards the front housing part anduniformly distribute the emitted light through the front housing part.For example, the light emitting component can include one or more of alight emitting diode (LED), a pinpoint LED lamp, an incandescent lightbulb, and a flexible light source. The light panel can include at leastone panel feature, such as a surface feature, and each panel featurecan, for example, direct the deflected light towards the front housingpart. The at least one panel feature can include one or more of aprinted pattern, a machined pattern, a molded pattern, a lens, a frostedcoating, and a semi-transparent coating positioned along a surface ofthe light panel. The at least one panel feature can include a pluralityof extrusions, and each of the plurality of extrusions can include oneor more of a sphere shape, a half-sphere shape, and a tubular shape.However, other shapes of the extrusions are within the scope of thisdisclosure.

In some embodiments, the front housing part can include a vacuumdeposition material that allows light to transmit therethrough therebyilluminating the front housing part when the light assembly is emittinglight and creates a metal, metallic, or chrome appearance to the fronthousing part when the light assembly is not emitting light. In someaspects, the front housing part can be three-dimensional. A front sideof the back housing part can include one or more of a reflective film, areflective tape, a reflective paint, a self-illuminating (e.g.,fluorescent) paint, and a light diffusing surface. A first part of thefront housing part can allow light to pass therethrough and a secondpart of the front housing part can prevent light from passingtherethrough. The back housing part can include an adhesive positionedalong a back side of the back housing part. An electrical lead canextend from the light assembly, such as through the back housing part,for connecting the light assembly to a power source.

In some embodiments, the light diffusing filler can include a coloredpigment. The light diffusing filler can be made out of one or more of aplastic, a urethane, a silicone, an epoxy, a one part curing resin, anda two part curing resin. The light diffusing filler can include amaterial that dissipates heat from the emblem assembly. The lightdiffusing filler can include a fluorescent dye that becomes illuminatedwhen light is emitted from the light assembly or from a secondary lightsource that is separate from the emblem assembly.

In some embodiments, the light assembly can include an LED light pipe.In some aspects, the light assembly can include an electroluminescentlight panel or electroluminescent wire.

In some embodiments, the emblem assembly includes a printed circuitboard (PCB) and an adapter. The adapter can couple a part of the lightassembly to the PCB. The adapter can include one or more of a lens, alight diffusing surface finish, a light directing pattern, and a lightcoloring element.

The details of one or more variations of the subject matter describedherein are set forth in the accompanying drawings and the descriptionbelow. Other features and advantages of the subject matter describedherein will be apparent from the description and drawings, and from theclaims.

DESCRIPTION OF DRAWINGS

The accompanying drawings, which are incorporated in and constitute apart of this specification, show certain aspects of the subject matterdisclosed herein and, together with the description, help explain someof the principles associated with the disclosed implementations. In thedrawings,

FIG. 1 illustrates a perspective cross-section view of an embodiment ofan illuminating emblem assembly consistent with implementations of thecurrent subject matter;

FIG. 2 illustrates a side cross section view of another embodiment of anilluminating emblem assembly of showing a part of the light assembly;

FIG. 3A illustrates a top view of a light assembly of an embodiment ofthe illuminating emblem assembly;

FIG. 3B illustrates a side view of the light assembly of FIG. 3A;

FIG. 3C illustrates a partial side view of the light assembly of FIG.3B;

FIG. 3D illustrates a side view of the adapter of FIG. 3B;

FIG. 3E illustrates various embodiments of surface features that can bepositioned along one or more sides of a light panel of the lightassembly of FIG. 3A, including various patterns and shapes of thesurface features;

FIG. 3F illustrates various light panel features, such as masks, thatcan be included on the light panel of the light assembly of FIG. 3A;

FIG. 4 illustrates a side view of another embodiment of the illuminatingemblem assembly, which includes a thermoformed face plate and a lightdiffusing filler material;

FIG. 5A illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly having distal ends of electrical leadsencapsulated in a filler material;

FIG. 5B illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly having electrical leads coupled tosubsurface conductive pads;

FIG. 5C illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly having electrical leads coupled toconductive tabs that are exposed through encapsulation by a fillmaterial;

FIG. 5D illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly having conductive pins extending fromthe light assembly that are configured to couple to a socket assembly;

FIG. 6 illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly including an inductive connection;

FIG. 7 illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly including a photovoltaic cellencapsulated with an external light source;

FIG. 8 illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly including at least one electricalcontact exposed through the fill material and coated with a self-healingpolymer;

FIG. 9 illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly including at least a part of a flexiblecircuit board encapsulated with at least one end of the circuit boardexposed and not encapsulated;

FIG. 10 illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly including an externally mounted springdriven contact pin that is exposed to an electrical contact pad;

FIG. 11 illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly including fiber optic cables exposedthrough fill material and illuminated by an external light source;

FIG. 12 illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly including a light pipe exposed throughfill material to an external light source;

FIG. 13 illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly including an encapsulated photovoltaiccell;

FIG. 14A illustrates a side cross-section view of another embodiment ofthe illuminating emblem assembly including a backing feature with abulkhead connection;

FIG. 14B illustrates an exploded side view of the illuminating emblemassembly of FIG. 14A;

FIG. 15A illustrates a perspective view of a downlight illuminatingemblem assembly that includes a back housing part configured to blocklight being radiated in one or more directions;

FIG. 15B illustrates a partially exploded view of the downlightilluminating emblem assembly of FIG. 15A;

FIG. 16 illustrates a perspective view of another embodiment of theilluminating emblem assembly having a submerged copper circuit board;

FIG. 17A illustrates a side cross-section view of an illuminating emblemassembly having a submerged bulkhead connector;

FIG. 17B illustrates a partial section view of the illuminating emblemassembly of FIG. 17A;

FIG. 18 illustrates a side view of another embodiment of an illuminatingemblem assembly having a light assembly that emits light directed alongor parallel to a plane along with a light panel of the light assemblyextends along;

FIG. 19A illustrates a bottom view of another embodiment of a lightassembly of an illuminating emblem assembly;

FIG. 19B illustrates another bottom view of the light assembly of FIG.19A;

FIG. 19C illustrates a side view of the light assembly of FIG. 19A; and

FIG. 19D illustrates a side view of the illuminating assembly includingthe light assembly of FIG. 19B.

When practical, similar reference numbers denote similar structures,features, or elements.

DETAILED DESCRIPTION

Described herein includes various embodiments of an illuminating emblemdevice that is configured to be coupled to a vehicle and/or device. Someimplementations of the illuminating emblem device include a lightassembly that is configured to provide a uniform (or substantiallyuniform) distribution of light along a front housing part or front panelof the illuminating emblem. For example, in some implementations, theilluminating emblem device can include a light diffusing filler thatdiffuses light emitted from the light assembly to assist with uniformlydistributing light emitted through the front housing part. The lightdiffusing filler can also serve to obscure aesthetically unpleasingfeatures positioned behind or within the light diffusing filler. Suchuniform distribution of light can provide an improved appearance offeatures associated with the illuminating emblem, as well as allow theilluminating emblem to be easily seen in dark and low-light conditions.Some embodiments of the illuminating emblem device described hereinincludes a light or light assembly that does not provide uniform orsubstantially uniform light distribution, such as to achieve particularaesthetics.

Some illuminating emblem devices described herein can be self-containedsuch that a light source of the light assembly is contained within ahousing of the illuminating emblem device, while also maintaining a lowprofile. In addition, the illuminating emblem device can include aself-contained and sealed light source that allows the illuminatingemblem device to be water resistant or water proof. In addition toimproved visibility and function, the illuminating emblem devicesdescribed herein can lower installation cost and maintenance, such asdue to having a compact and sealed design. In some embodiments, theilluminating emblem device can include coupling features that assistwith coupling the illuminating emblem device to a variety of surfaces,vehicles and devices.

In some embodiments, the illuminating emblem device can include variouselectronic configurations that are durable and low profile, as well asallow for efficient coupling of the illuminating emblem device to apower source. For example, various electrical connections between thelight assembly and a power source are described herein. Such connectionsallow for efficient and effective assembly of the illuminating emblem,thus minimizing assembly time and materials while still achieving thedesired uniform illumination of the illuminating emblem. Someilluminating emblem device embodiments are self-powered (e.g., include abattery) or do not require power (e.g., illuminating emblem devices thatinclude self-illuminating or fluorescent paints and/or fillers).

Methods of assembly of some of the illuminating emblem deviceembodiments are also described herein for example purposes such thatother assembly methods for achieving any of the embodiments disclosedherein are within the scope of this disclosure. The illuminating emblemdevice described herein can be coupled to any number of a variety ofdevices, such as vehicles (e.g., recreational vehicles, boats,motorcycles, jet skis, scooters, etc.), products, appliances (e.g.,refrigerators, stoves, washing machines, etc.), and/or the like withoutdeparting from the scope of this disclosure.

FIG. 1 illustrates a cross-section view of an embodiment of anilluminating emblem device 100 having a housing 102 that includes a faceplate or front housing part 106 coupled to a backing or back housingpart 108. An inner cavity 110 can be contained between the front andback housing parts 106, 108. The illuminating emblem device 100 canfurther include a light assembly 111 that is configured to emit light.At least a part of the front housing part 106 can be made out of one ormore materials that allow light emitted from the light assembly to passthrough the front housing part 106. The front housing part 106 can beformed of a rigid or semi-rigid formable sheet into a 3D shape. Theinner cavity 110 can at least partially be filled with a filler 112,such as a light diffusing filler. The filler 112 can be positionedadjacent, including surrounding, the light assembly 111. In someembodiments, the filler 112 can assist with positioning the lightassembly 111 within the inner cavity 110.

For example, the filler 112 can be made out of any number of materialsand can provide a number of features, including those discussed herein.For example, the filler 112 can be made out of a plastic, a urethane, asilicone, an epoxy, a one part curing resin, and a two part curingresin. The filler 112 can include a light diffusing urethane resin,which can be poured into the inner cavity 110 and allowed to solidify.The filler 112 can be delivered and allowed to harden or cure in theinterior cavity in one or more. Such layering can assist with eitherplacing the light source or light assembly at a correct position andorientation within the inner cavity 110 to achieve various visualeffects. The filler 112 can be clear when cured or can include a pigment(e.g., white, red, black, etc.).

In some embodiments, a light diffusing filler 112 a can be poured intothe front housing part 106 and the light assembly 111 can be placedbehind this light diffusing layer 112 a. A light blocking filler 112 bcan then be backfilled to cover a back side of the light assembly 111thereby assisting light emitted from the light assembly 111 to bedirected through the front housing part 106. For example, the lightassembly 111 can include a light panel (e.g., a white backlit modulepanel) that can be placed on a first layer surface of a light diffusingurethane resin (e.g., light diffusing filler 112 a layer) for assistingwith uniformly emitting light through the front housing part 106. Thelight blocking filler 112 b layer or other features can be backfilled orpositioned behind the light assembly 111 to encapsulate the lightassembly 111 and give the formed 3D front housing part 106 a rigid orsemi flexible strength. An adhesive (e.g., adhesive coating) 114 can beapplied at the time back filler is added or after the back filler iscured/solidifies. The adhesive can assist with coupling the illuminatingemblem device to a surface (e.g., vehicle, device, etc.).

The light assembly 111 can include any number of a variety of lightingfeatures that can assist with emitting light through the front housingpart 106. Furthermore, the light assembly 111 can emit lightsubstantially uniform across the front housing part 106. This canimprove the clarity of features associated with the illuminating emblemdevice 111, such as under dark or low-light conditions, as well asimprove the appearance and aesthetics of the illuminating emblem device100. The light assembly 111 and front housing part 106 can include anynumber of features, such as those described herein.

FIG. 2 illustrates a cross-section view of a part of an embodiment of anilluminating emblem device 200, which includes a light assembly 211 thathas at least one light source 220 coupled to a light panel 222. As shownin FIG. 2, the light assembly 211 can be contained between the fronthousing part 206 and back housing part 208 of the housing 202. Asdiscussed above, the light assembly 211 can be at least partiallyembedded in a filler 212, such as a light diffusing filler and/or any ofthe fillers discussed herein. The light source 220 can include one ormore of a variety of light sources, such as a light emitting diode(LED), a pinpoint LED lamp, an incandescent light bulb, and a flexiblelight source.

When the light source 220 is illuminated, the light emitted from thelight source 220 can be deflected off of the light panel 222 such thatthe light that is ultimately radiated through the front housing part 206is (or at least appears to be) uniform across a part of the fronthousing part 206 that allows light to be transmitted therethrough. Forexample, in some embodiments, the front housing part 206 can include afirst part that is made out of a translucent or transparent materialthat allows light to travel therethrough and a second part that is madeout of an opaque material that prevents light from travelingtherethrough. The light source 220 can be positioned relative to thelight panel 222 in a variety of configurations, such as positioned alongone or more sides of the light panel 222, as shown in FIG. 2.

Some configurations and embodiments of the light source 220 relative tothe light panel 222 can include an array of light sources 220 (e.g.,LED's) placed along a back side (e.g., side facing the back housing part208) of the light panel 222 and features in or on the light panel 222can be designed to distribute light emitted from the light sources 220to areas on the front housing part 206 to create a significantly uniformor “shaped” light distribution. The light sources 220 can be placedalong one or more sides or edges of the light panel 222 thereby allowingthe light emitted from the light sources 220 to be emitted through thefront housing part 106. For example, light emitted from the lightsources 220 can reflect off a one or more surfaces of the light panel222 (e.g., a surface facing the inside of the light panel 222 and/or asurface facing the outside of the light panel 222) in a direction thatis affected by a refractive index of the light panel 222. The angle ofincidence of the light on the light panel 222 can be referred to as aBrewster's angle. For example, light striking a surface facing theinside of the light panel 222 at an angle greater than the Brewster'sangle can be reflected back into the light panel 222 and can then beused by the light panel 222 to reflect out at an angle that is moreuseful (e.g., directed out the front housing part 206). In someembodiments, a row of light sources 220 can be placed on one or moreedges or even placed in specific areas of an edge or edges of the lightpanel 222 in order to achieve a specific light design objective. In someembodiments, light emitted from one or more light sources 220 can bereflected off shaped reflectors to create a desired lighting effect. Insome embodiments, the light panel 222 can include one or more holes orcavities that are sized and shaped to position at least one light sourcetherewithin, which can intensify and brighten light emitted from theselight sources.

In some embodiments, the light panel 222 can include one or more surfacefeatures 224 that can direct light, such as toward the front housingpart 206. For example, the surface features 224 can be on a frontsurface 223 (e.g., facing the front housing part 206) or back surface225 (e.g., facing the back housing part 208) of the light panel 222 andcan disperse light emitted from the light assembly 211 to illuminatespecific areas of the front hosing part 206. Such surface features 224can be printed, machined, cast stamped, and/or added to the panel. Thesurface features 224 can include any number of shapes andconfigurations. For example, the surface features 224 can each have asmall circular shape and can be placed in such a way to either achieve alargely uniform light field or selectively direct light from the lightpanel 222 (e.g., intensify light in some directions and reduce lightintensity in other directions). The surface features 224 can includeinkjet or screen printed patterns, machined patterns, molded patterns,small lenses, and/or areas with obscured surfaces such as frosted orsemi-transparent finishes and/or masks. The surface features 224patterns can include any of a variety of patterns, such as grids,meshes, and/or other shapes. The light panel 222 can have a variety ofshapes and sizes, including having one or more individual segments thatare shaped to define a desired light output. Such segments may or maynot be mechanically linked as well as electrically linked.

In some implementations, the surface features 224 can be fabricated byprinting the pattern on the light panel 222 using a multiplicity ofprinting techniques, such as silk screening, mask and spray painting,thermal coining, hot stamp applied thermal inks or foils, pressuresensitive pre-printed films, and the like. Additionally oralternatively, the surface features 224 can be machined or cast into thelight panel 222. The surface features 224 and/or light panel 222 caninclude acrylic plastics, polycarbonates, styrene, or other materialsthat can be shaped and/or cast. The surface features 224 can includematerial that either reflects, absorbs, or diffuses light. In someembodiments, one or more light diffusing layers can be included furthergive the appearance of uniform light using diffusion. For example, thelight panel 222 can include a substrate with high internal reflectivitythat can be overlaid with an opaque material cut into a specific patternthat is overlaid with a colored transparent or semi-transparentmaterial, which can filter patterns of light transmission created.

In some embodiments, one or more edges of the light panel 222 caninclude a light reflective material that can redirect lost light to thefront housing part 206. In some embodiments, the light panel 222 caninclude a light enhancement film with one or more facets and/or othershapes to redirect light that was not released at a useful angle to onethat is more useful (e.g., towards the front housing part 206). In someembodiments, the light diffusing filler 212 can include a clear materialhaving titanium dioxide, calcium carbonate, and/or other light diffusingcolor pigments or particles suspended or coated on the surface of thelight diffusing filler 212. In some embodiments, small glass spheres canbe included in the light diffusing filler to create uniform foam havinglight diffusing properties without tinting the light diffusing filler212. Alternatively or in addition, the light diffusing filler 212 caninclude a clear plastic sheet with micro-machined grooves or featuresthat disrupt and scatter the light.

FIGS. 3A-3F illustrate another embodiment of the illuminating emblemdevice 300 having a light panel 322 coupled to one or more adapters 330.Each adapter 330 can be configured to couple a light source 320 to thelight panel 322, as well as assist with positioning the light panel 322relative to a circuit board (or PCB) 335 upon which the light panel 322can be coupled to. When illuminated, the light source 320 can directlight onto the light panel 322. The light panel 322 can assist withdistributing the light evenly and/or preferentially along the fronthousing part of the illuminating emblem 300. FIG. 3C shows, for example,the adapter 330 coupled to the light panel 322, the light source 320coupled to the adapter 330, and the adapter 330 coupled to the circuitboard 335. The light panel 322 can include a diffusion film on one orboth sides that can assist with diffusing light emitted from the lightsource 320. The adapter 330 can include a locator pin 332 that canassist with positioning the light panel relative to the circuit board.FIG. 3D illustrates example, retaining features 333 (e.g., opposingclamp arms) that are configured to couple the light source 320 to theadapter 330. The adapter 330 can also include light panel retentionfeatures 334 that assist with coupling the light panel 322 to theadapter 330. The adapter 330 can include any number of features (e.g.,coated to increase reflectivity and reduce light loss) and provide anumber of functions, such as allowing for tuning of the illuminationand/or provide optics for light modification. In some embodiments, forexample, one or more adapters 330 can include reflective properties thatallow at least a part of the adapter 330 to reflect light emitted fromthe light source, such as in a focused, diffused or shaped manor. Forexample, such adapters 330 having reflectors can be shaped in aparabolic, Gregorian, off axis, planar, hyperbola, or elliptical shape.For example, the adapter 330 can be made out of one or more materialsthat can provide Lambertian or other light scattering effects, as wellas specular reflection. In some embodiments, the adapter can include oneor more shapes that assists with shaping and/or directing light, such asa prism, dimple, pyramid, half sphere, etc. Such adapter shapes can beuniform, such shapes found in light management films, or can be randomshapes having varying sizes, spacing, and shaping (e.g., a texturedsurface). Some embodiments of the adapter 330 can thus focus, create alighting effect, or redirect light emitted from the light source 320,such as to prevent light loss, (e.g., from areas close to the edge ofthe light panel 322).

FIG. 3E illustrates various printed surface features 324 of the lightpanel 322 associated with the light assembly 311. The surface features324, for example, can be printed on a surface of the light panel 322 andcan be varied (e.g., size, shape, color, pitch, diameter, patterndensity, etc.) to allow different amounts and/or effects of light topass through. Some embodiments of the surface features 324 can includeprinted or extruded dots. For example, the surface features 324 can bemade from materials with a similar refractive index as the light panel322, which can contain pigments or other materials that change thenature of the light by reflecting, absorbing or dispersing the light insome way. The surface features 324 can also be made from a resin orcoating (e.g., having a significantly different refractive index fromthe light panel 322). As such, for example, the light can be bent,refracted or allowed to transmit in a variety of ways. In someembodiments, for example, the surface features 324 can be approximately0.001 inch thick and approximately 1 millimeter in diameter. In someembodiments, one or more white reflector panels 339 (as shown in FIG.3C) can also be placed adjacent or along one or more sides of the lightpanel 322. The white reflector panels 339 can reflect the light exitingthe light panel 322 back into the lamp panel 322, thereby allowing thelight to be reflected in a different direction.

FIG. 3F illustrates various features that can be coupled to a lightpanel 322, such as one or more masks 338. For example, a mask 338 can beapplied to one or more surface areas of the light panel 322 to modifythe light or illumination provided by the device. Some masks can includecolored patterns that can provide, for example, colored and uniformemitted light through the front housing part. In addition, some maskscan be opaque thereby preventing light to pass through. Some embodimentsof the masks having a colored appearance can be made from one or morepigments or dyes applied to a surface of the lamp panel using any numberof techniques, such as printing, sublimation, ink jetting, foiltransfer, painting, etc. Some colored masks can be made from a plasticfilm that includes light filtering pigments or dyes therewithin. Acolored mask can also include a clear base material with a coat of lightaltering pigments or dyes applied thereon. Some embodiments of the maskcan include a transparent, semi-transparent or translucent film that hasone or more areas of colorant, pigment or dye applied to the surface.

In some embodiments, one or more surfaces of the adaptor 330 can includeat least one feature that can focus, diffuse, and/or otherwise modifythe light emitted from the light source 320. These adaptor surfacefeatures can include one or more lenses, surface finishes, variouspatterns, and/or masks or colored elements. Such adaptor surfacefeatures can direct, encourage, and/or prohibit light propagation.

In some embodiments, the front housing part can include a vacuumdeposition material that allows light to transmit therethrough therebyilluminating the front housing part when the light assembly is emittinglight and creates a metal, metallic, or chrome appearance to the fronthousing part when the light assembly is not emitting light. In someembodiments, a front side of the back housing part can include one ormore of a reflective film, a reflective tape, a reflective paint, aself-illuminating (e.g., fluorescent) paint, and a light diffusingsurface. Furthermore, in some embodiments, a first part of the fronthousing part can allow light to pass therethrough and a second part ofthe front housing part can prevent light from passing therethrough.

FIG. 4 illustrates another embodiment of the illuminating emblem device400, which includes a thermoformed front housing part 406 that is filledwith a light diffusing filler 412, such as any of the light diffusingfiller 412 described herein. The illuminating emblem device 400 shown inFIG. 4 can include a light assembly 411 that includes a light source 420coupled to a light panel 422 via an adapter 430 and can be containedwithin the light diffusing filler 412. As shown in FIG. 4, an adhesivecoating or layer 414 can be positioned along a back side of theilluminating emblem device 400 for assisting with coupling the device400 to a surface. The adhesive 414 can be pressure sensitive and/ordouble sided or could be heat activated.

Any of the illuminating emblem devices described herein can include avariety of electrical connections and power assemblies that assist withproviding power to the light assembly. Various embodiments of suchelectrical connections and power assemblies are illustrated anddescribed herein. Other embodiments are also within the scope of thisdisclosure.

FIG. 5A illustrates another embodiment of the illuminating emblem device500 having distal ends of electrical leads 550 encapsulated in the lightdiffusing filler 512 that also encapsulates the light assembly 511. Thedistal ends of the leads can be coupled (e.g., soldered) to the circuitboard 535, which can be electrically connected to the light source 520.The embodiment of the illuminating emblem device 500 can include anelectrical connection where there are no intermediary connections,connectors or other points of failure between the electrical leads 550and the light assembly 511.

FIG. 5B illustrates another embodiment of the illuminating emblem device600 including electrical leads 650 coupled to subsurface conductive pads652. The subsurface conductive pads 652 can be connected (e.g.,soldered) to the circuit board 635 and the distal ends of the electricalleads 650 can be coupled to the subsurface conductive pads 652 (e.g.,after backfilling with light diffusing filler 612), such as usingmechanical features (e.g., screws). The subsurface conductive pads 652can prevent interference with a backfilling operation. The electricalleads 650 can include non-conductive sleeves that prevent shorting.

FIG. 5C illustrates another embodiment of the illuminating emblem device700 having electrical leads 750 coupled to the circuit board 735 and areexposed through encapsulation by the light diffusing filler 712. Theadditional potting or light diffusing filler 512 in this embodiment canprotect sensitive electronics from water ingress, thereby making thedevice 700 water resistant or water proof.

FIG. 5D illustrates another embodiment of the illuminating emblem device800 having conductive pins 854 extending from the light assembly 811that are configured to couple to a socket assembly 856. The socketassembly 856 can be coupled to electrical leads 850 that extend to apower source. For example, this embodiment of the illuminating emblemdevice 800 can allow a user to easily connect and disconnect the powersource to the illuminating emblem device 800.

FIG. 6 illustrates another embodiment of the illuminating emblem device900 coupled to a surface 901 including an inductive connection withencapsulated coils 960 extending between the light assembly 911 andelectrical leads 950. For example, at least two antennae 952 and aninductance are used to transmit electricity across a gap of anon-conducting material, such as air, adhesive, fiberglass materials,plastics. Depending upon the tuning of the antennae 952 and theelectronics, the size of the gap between the sending antenna andreceiving antenna of the inductive circuit can transmit more electricalpower than needed to power the light source 920, which can have arelatively low electrical consumption. For example, this embodiment canprovide an advantage of having a submerged light assembly 911 and powersource or circuitry so the device 900 can be efficiently manufacturedand coupled to, for example, the surface 901 of a vehicle or device. Theinductive power circuitry can offer an additional advantage in that boththe sender and receiver electronics can be potted or molded in a waythat make both substantially waterproof. For example, a hole does notneed to be opened up in the sidewall of a boat, RV or other product, butrather a completely sealed wall can be built on the sender side to housethe sender. As such, the sender and receiver can be completely hiddenand a completely waterproof illuminating emblem device 900 can result.

FIG. 7 illustrates another embodiment of the illuminating emblem device1000 including a photovoltaic cell 1065 encapsulated with an externallight source 1066. The photovoltaic cell 1065 along with a battery 1068can be embedded within the housing 1002 or inner cavity 1010 of thefront housing part 1006 in a way that allows charging of the battery1068 in the daytime for use at night. A controlling circuit can beprovided that switches between charging mode in daytime use,self-contained powered mode at night, and an additional powered modewhen the unit can be powered by the battery or normal electrical systemof the unit it is attached to. The controlling circuit can be automatedand/or controlled by a user. This can offer the advantage of having anilluminating emblem device 1000 that lights up at night without drainingthe battery 1068.

In some embodiments, the solar cell and battery can be embedded in thehousing 1002 thereby making the illuminating emblem device 1000completely self-contained without any external wiring or holes, such asin the back housing part 1006. Some embodiments can include thefollowing: a self-contained battery with charging coming from anexternal solar cell; a self-contained battery that is charged by avehicle power supply when energized; an illuminating emblem device 1000that is powered by an additional external module that contains a batteryand a charger energized by the vehicle electrical system when thevehicle is operating. Such embodiments can reduce or eliminate the needfor external power, such as when the emblem is illuminated.

FIG. 8 illustrates another embodiment of the illuminating emblem device1100 including at least one electrical contact 1170 exposed through thelight diffusing filler 1112 and coated with a self-healing polymer 1172.For example, the self-healing polymer 1172 can include a soft siliconeor urethane that allows a conductor to penetrate and make contact with atarget underneath. For example, the self healing polymer can flow arounda conductor thereby making it water resistant or waterproof

The self-healing polymer 1172 can allow a connection to be made betweenthe electrical contacts 1170 and the light assembly 1111 under a surfaceof the self-healing polymer 1172 without further potting. This can allowthe self-healing polymer 1172 to be submerged under a surface ofadhesive 1114. In this way the electrical connections and self-healingpolymer 1172 do not interfere with the filling or potting process usingthe light diffusing filler 1112. Other electrical connections andconnectors (e.g. needle-like connections 1174) can be included in thedevice 1100 (e.g., after the electrical contact 1170 connection is made)using a method that minimally disturbs the adhesive 1114 andself-healing polymer 1172, as well as prevent water ingress into thedevice 1100.

FIG. 9 illustrates another embodiment of the illuminating emblem device1200 including a flexible circuit board 1280 encapsulated with aproximal end exposed through an encapsulating material 1282. Theaddition of the flexible circuit board 1280 can eliminate the need toconnect wires or electrical leads 1250 to an embedded circuit board butrather to extend the flexible circuit board 1280 out through the back ofthe illuminating emblem device 1200. For example, this can makemanufacturing more efficient and cost effective by combining the stepsof making a circuit of lights and adding wires to that circuit.

FIG. 10 illustrates another embodiment of the illuminating emblem device1300 including an externally mounted spring driven contact pin 1385 thatis exposed to an electrical contact pad 1387. The spring of the springdriven contact pin can assist with maintaining contact between the pinand contact pad 1386. For example, this illuminating emblem device 1300can be free from wires, which can make mounting the device 1300 easierand more efficient.

The illuminating emblem can include any number of a variety of lightingassemblies, including light sources, for assisting with illuminating theemblem. Various embodiments of such lighting assemblies are illustratedand described herein. Other embodiments are also within the scope ofthis disclosure.

FIG. 11 illustrates another embodiment of the illuminating emblem device1400 including a light assembly 1411 having at least one fiber opticcable 1488. The fiber optic cable 1488 can be exposed to filler orencapsulating material 1482 and illuminated by an external light source1489. The external light source 1489 can be positioned outside of theinner cavity 1410 of the front housing part 1406, such as shown in FIG.11. This embodiment can alternatively, or in addition, including aninternal light source.

FIG. 12 illustrates another embodiment of the illuminating emblem device1500 including a light assembly 1511 having a light pipe 1590, which canbe exposed to filler or encapsulating material and/or an external lightsource 1589. The light pipe 1590 can also provide support for otherparts of the light assembly 1511, such as the light panel 1522. Thelight pipe 1590 can move the electronics and light generation out of thehousing 1502 and to a sender unit. The sender unit (light generator) andreceiver unit (illuminating emblem) can work together in such a way asto uniformly distribute light emitted from the light pipe 1590.

The receiving unit (e.g., illuminating emblem device 1500) can include alight distribution system that uses mirrors, lenses, and/or the like toredirect the light throughout the illuminating emblem. Such anembodiment of the device 1500 can be void of electronics and be waterresistant or water proof. In some embodiments, the light pipe 1590 caninclude internal reflectivity, be either hollow or solid, and/ortransmit non-image light along its length. The emissive end of the lightpipe 1590 can have a shape designed to specifically disperse the lightin a preferential manner. Such light pipes 1590 can also interface withother light pipes or other light conductive structures to distribute thelight in preferential patterns.

FIG. 13 illustrates another embodiment of the illuminating emblem device1600 including an electrical storage device 1692, such as a battery.Such electrical storage device 1692 can be positioned within the housing1602 or inner cavity 1610 of the illuminating emblem device 1600. Insome embodiments, the electrical storage device 1692 can include aphotovoltaic cell and can be encapsulated for charging by ambient light.Some implementations can include light detection such that the one ormore light sources of the light assembly 1611 can be turned on oncelow-light is detected. A timer can be implemented in the illuminatingemblem device 1600 that can be configured to turn off the light after apredetermined or set time.

For example, some embodiments of the illuminated emblem device canilluminate without conducting electricity to the housing or within theinner cavity of the illuminating emblem device. Such embodiments of theilluminating emblem device can be resistant from water and able to beexposed to various fumes and/or vapors without interfering with itsfunctioning. Encapsulation of the major light conducting components,minimal exposure of the conducting elements, and a seal provided by thepressure sensitive adhesive tape/foam laminate used for attachment canalso assist with such water and environment proofing.

FIGS. 14A-14B illustrate another embodiment of the illuminating emblemdevice 1700 including a coupling feature 1795 that includes a bulkheadconnector 1796. Encapsulation or light diffusing filler can bond to andbackfill a part of the coupling feature 1795. In some methods ofmanufacturing, the illuminating emblem device 1700 can be assembled andencapsulated at the same time. The emblem device 1700 can be assembledonto a backing having the bulkhead connector 1796 under controlledconditions that can create an improved waterproof connection. It is wellknown that directing wires through holes can create rough surfaces thatthe wires can rub against. These rough surfaces can abrade the wiresover time and destroy the conductive capability of the wires. As such,the bulkhead connection 1796 can create a protective conduit throughwhich the electrical leads 1750 can be protected.

In some methods of manufacturing, the illuminating emblem device shownin FIGS. 14A-14B can include a coupling feature 1795 that is notattached at the time of encapsulation of the components (e.g., lightassembly 1711). For example, the encapsulated components can be attachedto the coupling feature 1795 using two sided adhesive tape, adhesive1714, mechanical means such as fasteners or the like. Conducting leads1750 can extend from the light assembly 1711 and can be sealed using avariety of compounds such as resins, sealers, adhesives, etc. Forexample, the illuminating emblem device 1700 can be attached to astructure using a single fastener (e.g., nut 1740) or a plurality offasteners. Additionally, the bulkhead device 1795 can be shaped anddecorated in a way that is visible from the front side to be anaesthetic addition to the lit emblem much like a trim piece.

FIGS. 15A-15B illustrate a downlight illuminating emblem device 1800that can include one or more of the features described above, as well asa base or back housing part 1808 that is configured to block light beingemitted from the light assembly 1811 in one or more directions. In someembodiments, the back housing part 1808 can be made out of a lightblocking filler (e.g., light blocking acrylic). The illuminating emblemdevice 1800 can also include light diffusing filler 1812 that allowslight to exit in one or more areas. The light source 1820 can include anLED panel or strip 1842 that extends along a back side of the fronthousing part 1806. The downlight illuminating emblem device 1800 canalso include a light filter positioned adjacent the LED strip 1842.

FIG. 16 shows an illuminating emblem device 1900 having a submergedcopper circuit board 1945 (e.g., one or more copper circuit board 1945that are encapsulated in the light diffusing filler 1912). For example,electrical leads 1950 can extend between the light assembly 1911 and thecopper circuit board 1945. In some embodiments, the copper circuit board1945 can be adhered to the light assembly 1911 or submerged behind thelight assembly 1911 during the backfill operation (e.g., after the lightassembly 1911 has been at least partially encapsulated). Somemanufacturing advantages can include the copper circuit board 1945 beingbackfilled without elements protruding through an adhesive 1914 alongthe back side of the illuminating emblem device 1900. Some methods ofmanufacturing, for example, can include one or more of the followingsteps: 1) connect and position the copper plate 1945 on the back of thelight source; 2) backfill with light diffusing filler 1912, applyadhesive 1914, and allow light diffusing filler 1912 to cure; 3) cut theadhesive 1914 and down through the backfill to the copper circuit board1945 and remove a backfill/adhesive plug; 4) connect electrical leads1950 to the copper circuit board 1945; 5) backfill space where backfilland adhesive was removed.

FIGS. 17A-17B show an illuminating emblem device 2000 having a submergedbulkhead connector 2046 (e.g., a bulkhead connector that is at leastpartially encapsulated in the light diffusing filler 2012). In someembodiments, one or more pins 2200 can engage with or be coupled to thesubmerged bulkhead connector 2046 to provide a conductive pathway to oneor ore more light sources. Some methods of manufacturing, for example,can include one or more of the following steps: 1) one or more lightsource connection wires can be connected to the pins 2200; 2) a bulkheadconnector 2046 can be affixed to the back of the light source 2020 insuch a way that it can be located at a later time and the connector caninclude a pocket that is laminated with tape (or similar material) tokeep backfill from filling the connector area; 3) The light diffusingfiller 2012 can be backfilled and adhesive laminated; 4) the location ofthe air pocket can be located and the adhesive 2014 can be cut andremoved thereby opening the bulkhead connector 2046; 5) a connectionbetween the light source 2020 and a power source can be made either byplugging, soldering or other method. The bulkhead connector 2046 can bemolded in such a way to prevent ingress of water. This can prevent awell-known issue where the wires exiting the backfill can allow ingressof water down the outside of the wires from lack of bonding to the wireinsulation or stress on the wires that open up channels for leakage.

FIG. 18 illustrates a side view of another embodiment of an illuminatingemblem assembly 3000 mounted to a surface 3001 (e.g., via an adhesivelayer 3114 along a back housing part 3108) having a light assembly 3111that emits light directed along or parallel to a plane along which alight panel 3122 of the light assembly 3111 extends along. This canallow light to be directed through a side surface 3110 (e.g., top side,bottom side, left or right side) of the front housing part 3106. Lightcan also be emitted at other angles through the front housing part 3106,such in a direction perpendicular to a front surface of the light panel3122. As such, the illuminating emblem assembly 3000 can provideillumination of the features associated therewith (e.g., emblem featuresalong the front housing panel 3106) as well as provide illumination offeatures, elements, etc. positioned adjacent to the illuminating emblemassembly 3000.

As shown in FIG. 18, the illuminating emblem assembly 3000 can include alight panel 3122 with a row of light sources 3120 (e.g., LED's) on afirst side (e.g., top side) of the light panel 3122 and an opposing side(e.g., bottom side) of the light panel 3122 can be free frominterference (e.g., no lights or light-blocking films) thereby allowingthe light emitted from the row of light sources can be emitted from theopposing side and through a side surface (e.g., side surface 3110) ofthe front housing part 3106. Such light can also pass through a filler3112 (e.g., light diffusing) and/or through a transparent chrome-likematerial. Various other embodiments and configurations are within thescope of this disclosure, such as including a first strip of LED'spositioned along a bottom side of the light panel 3122 that projectslight up into the light panel, as well as another strip of LED's back toback with the first strip that sends light in the opposite direction.

FIGS. 19A-19D illustrate another embodiment of an illuminating emblemassembly 4000 having a light assembly 4600 that can be included in theilluminating emblem assembly 4000. The light assembly 4600 can includean acrylic panel 4112 with at least one light source 4120 (including arow or string of light sources) positioned along a side of the acrylicpanel 4122, such as is shown in FIGS. 19A and 19B. For example, thelight source 4120 can be taped or glued along the side of the acrylicpanel 4122. Sides of the acrylic panel 4122 that do not include thelight source 4120 can include a white vinyl material 4250 that reflectslight into the acrylic panel 4122 to allow the light to eventually bedirected out through the front housing part 4106. As shown in FIG. 19A,a back side 4113 of the acrylic panel 4122 can include surface featuresor light management features 4224 that can direct and effect the lightemitted from the light source 4120, such as direct the light through thefront housing part 4106. A white styrene material 4100 can be positionedover the back side 4113 having the surface features 4224 and circuitboard 4335 can be coupled to a back side 4115 of the white styrene 4100,as shown in FIGS. 19B and 19C. An electrical lead 4150 can extend and becoupled between the light source 4120 and the circuit board 4335. Asshown in FIG. 19C, one or more layers of a textured clear polycarbonate4200 a, 4200 b can be positioned or adhered along a front side 4110 ofthe acrylic panel 4112, which can assist with concealing the componentsof the light assembly 4600 while not blocking light transmission. Aclear vinyl material 4500 can be wrapped around the assembly, as shownin FIG. 19C, thereby preserving air layers within the light assembly4600.

During assembly, the front housing part 4106 can be at least partlyfilled with a first layer of fill material 4112 a, such as a lightdiffusing filler, and the light assembly 4600 can be positioned on topsurface of the first layer of fill material 4112 a. Once the first layerof fill material is cured, a second layer of fill material 4112 b, suchas a light-blocking filler, can be poured over the first layer of fillmaterial 4112 a and light assembly 4600, thereby covering a back side ofthe light assembly 4600. An adhesive can be added to the top of thebackfill or back housing side 4108. A laser cutter or other device canbe used to cut away some of the cured second layer of fill material 4112b to access the circuit board 4335 for mating an electric coupling 4700thereto. The electric coupling can include a collar that secureselectrical wires extending from the light assembly 4600.

In the descriptions above and in the claims, phrases such as “at leastone of” or “one or more of” may occur followed by a conjunctive list ofelements or features. The term “and/or” may also occur in a list of twoor more elements or features. Unless otherwise implicitly or explicitlycontradicted by the context in which it is used, such a phrase isintended to mean any of the listed elements or features individually orany of the recited elements or features in combination with any of theother recited elements or features. For example, the phrases “at leastone of A and B;” “one or more of A and B;” and “A and/or B” are eachintended to mean “A alone, B alone, or A and B together.” A similarinterpretation is also intended for lists including three or more items.For example, the phrases “at least one of A, B, and C;” “one or more ofA, B, and C;” and “A, B, and/or C” are each intended to mean “A alone, Balone, C alone, A and B together, A and C together, B and C together, orA and B and C together.” Use of the term “based on,” above and in theclaims is intended to mean, “based at least in part on,” such that anunrecited feature or element is also permissible.

The implementations set forth in the foregoing description do notrepresent all implementations consistent with the subject matterdescribed herein. Instead, they are merely some examples consistent withaspects related to the described subject matter. Although a fewvariations have been described in detail herein, other modifications oradditions are possible. In particular, further features and/orvariations can be provided in addition to those set forth herein. Forexample, the implementations described above can be directed to variouscombinations and sub-combinations of the disclosed features and/orcombinations and sub-combinations of one or more features further tothose disclosed herein. In addition, the logic flows depicted in theaccompanying figures and/or described herein do not necessarily requirethe particular order shown, or sequential order, to achieve desirableresults. The scope of the following claims may include otherimplementations or embodiments.

What is claimed is:
 1. An emblem assembly, comprising: a housingincluding a front housing part coupled to a back housing part and aninner cavity contained between the front housing part and back housingpart; a light assembly configured to emit light and positioned withinthe inner cavity; and a light diffusing filler contained within theinner cavity and positioned adjacent the light assembly to diffuse atleast some of the light emitted from the light assembly, wherein atleast a part of the front housing part allows the diffused light emittedfrom the light assembly to pass therethrough.
 2. The emblem assembly ofclaim 1, wherein the light assembly includes at least one light sourcecoupled to a light panel, wherein the light panel is configured todeflect light emitted from the at least one light source towards thefront housing part and uniformly distribute the emitted light throughthe front housing part.
 3. The emblem assembly of claim 2, wherein thelight source includes one or more of a light emitting diode (LED), apinpoint LED lamp, an incandescent light bulb, and a flexible lightsource.
 4. The emblem assembly of claim 2, wherein the light panelincludes at least one surface feature, wherein each surface featuredirects the deflected light towards the front housing part.
 5. Theemblem assembly of claim 4, wherein the at least one surface featureincludes one or more of a printed pattern, a machined pattern, a moldedpattern, a lens, a frosted coating, and a semi-transparent coating. 6.The emblem assembly of claim 4, wherein the at least one surface featureincludes a plurality of extrusions, wherein each of the plurality ofextrusions includes one or more of a sphere shape, a half-sphere shape,and a tubular shape.
 7. The emblem assembly of claim 1, furthercomprising a layer of clear vinyl material positioned between the lightassembly and the light diffusing filler
 8. Further including a lightblocking filler positioned adjacent the light assembly, the lightblocking filler preventing light from passing therethrough.
 9. Theemblem assembly of claim 1, wherein the front housing part includes avacuum deposition material that allows light to transmit therethroughthereby illuminating the front housing part when the light assembly isemitting light and creates a metallic or chrome appearance to the fronthousing part when the light assembly is not emitting light.
 10. Theemblem assembly of claim 1, wherein the front housing part isthree-dimensional.
 11. The emblem assembly of claim 1, wherein a frontside of the back housing part includes one or more of a reflective film,a reflective tape, a reflective paint, a self-illuminating paint, and alight diffusing surface.
 12. The emblem assembly of claim 1, wherein thelight diffusing filler is made out of one or more of a plastic, aurethane, a silicone, an epoxy, a one part curing resin, and a two partcuring resin.
 13. The emblem assembly of claim 1, wherein a first partof the front housing part allows light to pass therethrough and a secondpart of the front housing part prevents light from passing therethrough.14. The emblem assembly of claim 1, wherein the back housing partincludes an adhesive positioned along a back side of the back housingpart for assisting with coupling the emblem assembly to a surface. 15.The emblem assembly of claim 1, further comprising an electrical leadextending from the light assembly and through the back housing part forconnecting the light assembly to a power source.
 16. The emblem assemblyof claim 1, wherein the light diffusing filler includes one or more of acolored pigment and a material that dissipates heat from the emblemassembly.
 17. The emblem assembly of claim 1, wherein the lightdiffusing filler includes a fluorescent dye that becomes illuminatedwhen light is emitted from the light assembly or from a secondary lightsource that is separate from the emblem assembly.
 18. The emblemassembly of claim 1, wherein the light assembly includes an LED lightpipe.
 19. The emblem assembly of claim 1, wherein the light assemblyincludes an electroluminescent light panel or electroluminescent wire.20. The emblem assembly of claim 1, further comprising a printed circuitboard (PCB) and an adapter, the adapter coupling a part of the lightassembly to the PCB, and wherein the adapter includes one or more of alens, a light diffusing surface finish, a light directing pattern, and alight coloring element.